Zwitterionic Nanocarrier Surface Chemistry Improves siRNA Tumor Delivery and Silencing Activity Relative to Polyethylene Glycol Meredith A. Jackson, Thomas A. Werfel, Elizabeth J. Curvino, Fang Yu, Taylor E. Kavanaugh, Samantha M. Sarett, Mary D. Dockery, Kameron V. Kilchrist, Ayisha N. Jackson, Todd D. Giorgio, and Craig L. Duvall* Department of Biomedical Engineering, Vanderbilt University, Nashville, Tennessee 37240, United States S Supporting Information *
ABSTRACT: Although siRNA-based nanomedicines hold promise for cancer treatment, conventional siRNA− polymer complex (polyplex) nanocarrier systems have poor pharmacokinetics following intravenous delivery, hindering tumor accumulation. Here, we determined the impact of surface chemistry on the in vivo pharmacokinetics and tumor delivery of siRNA polyplexes. A library of diblock polymers was synthesized, all containing the same pH-responsive, endosomolytic polyplex core-forming block but different corona blocks: 5 kDa (benchmark) and 20 kDa linear polyethylene glycol (PEG), 10 kDa and 20 kDa brush-like poly(oligo ethylene glycol), and 10 kDa and 20 kDa zwitterionic phosphorylcholine-based polymers (PMPC). In vitro, it was found that 20 kDa PEG and 20 kDa PMPC had the highest stability in the presence of salt or heparin and were the most effective at blocking protein adsorption. Following intravenous delivery, 20 kDa PEG and PMPC coronas both extended circulation half-lives 5-fold compared to 5 kDa PEG. However, in mouse orthotopic xenograft tumors, zwitterionic PMPC-based polyplexes showed highest in vivo luciferase silencing (>75% knockdown for 10 days with single IV 1 mg/kg dose) and 3-fold higher average tumor cell uptake than 5 kDa PEG polyplexes (20 kDa PEG polyplexes were only 2-fold higher than 5 kDa PEG). These results show that high molecular weight zwitterionic polyplex coronas significantly enhance siRNA polyplex pharmacokinetics without sacrificing polyplex uptake and bioactivity within tumors when compared to traditional PEG architectures. KEYWORDS: siRNA polyplexes, zwitterionic, phosphorylcholine, pharmacokinetics, tumor delivery of the majority of the injected dose.5,6 Polyplexes can disassemble in circulation when they encounter serum proteins that penetrate polymer coronas or anionic heparan sulfates at the kidney glomerular basement membrane that compete with electrostatic interactions between polymer and siRNAs; free uncomplexed siRNA is then rapidly filtered for removal in the urine.6−8 Moreover, protein adsorption significantly affects biodistribution of polyplexes by marking them for recognition and phagocytosis by macrophages of the mononuclear phagocyte system (MPS) and/or potentially activating the complement pathway.5,9,10 Polyplex surface chemistry is one of the most influential factors determining pharmacokinetics in vivo because physicochemical surface properties like charge and hydrophilicity
T
here has been great interest in the development of small interfering RNAs (siRNAs) as human therapeutics for a variety of diseases, including cancer, with over 50 clinical trials completed or currently in progress.1,2 However, because of the poor pharmacokinetic properties of free siRNA, there remains an unmet need for carriers with optimized systemic bioavailability and delivery to solid tumors.3 Because tumors are perfused with a relatively small fraction of the body’s blood volume, siRNA therapeutics must remain stable and inert in the systemic circulation for extended time in order to maximize the opportunity for passive accumulation within a tumor.4 The carrier must also be actively internalized and retained within the tumor cells rather than being transported back out of the tumor or being reabsorbed into the systemic circulation. Upon intravenous administration, polyplexes encounter diverse delivery challenges that cause polyplex destabilization and/or removal by phagocytic cells, resulting in rapid clearance © 2017 American Chemical Society
Received: February 16, 2017 Accepted: May 26, 2017 Published: May 26, 2017 5680
DOI: 10.1021/acsnano.7b01110 ACS Nano 2017, 11, 5680−5696
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Figure 1. siRNA polyplexes containing varied corona architectures. All polymers contain the same polyplex core-forming block consisting of equimolar DMAEMA and BMA. The corona-forming blocks comprise either linear PEG, zwitterionic PMPC, or brush PEG structures (POEGMA), as pictured. Polymer structures are displayed on the left, with the core-forming block in red and corona-forming block in blue. Polymers are complexed with siRNA at low pH, triggering spontaneous assembly of polyplexes before the pH is raised to physiological pH.
stability, cell uptake, and pharmacokinetics of some nanocarriers relative to both PEGylated and unmodified carriers.21,22 One type of zwitterion, phosphorylcholine, has found particularly widespread use for antifouling applications and is a component of FDA-approved contact lenses and drug-eluting stents.19,23,24 Phosphorylcholine-based polymers (e.g., polymethacryloyloxyethylphosphorylcholine, PMPC) are hemocompatible, easy to synthesize, and can mimic nonthrombogenic surfaces of red blood cells (RBCs), which contain many phosphorylcholine groups. In the context of nucleic acid delivery, Ukawa and colleagues have used PMPC coatings in GALA-modified lipid nanoparticles to increase their plasmid DNA transfection in vitro.25 PMPC has also been recently applied for tumor delivery of siRNA in vivo. Yu and colleagues used PMPC-based cationic polymers to intravenously deliver siRNA against MDM2, reducing NSCLC tumor growth in vivo compared to scrambled controls, but there was no analysis of pharmacokinetics, no analysis of per cell particle uptake, and no comparison to PEGylated polyplexes.26 There remains a need to comprehensively benchmark PMPC against traditional PEG architectures for in vivo pharmacokinetics, siRNA delivery, and activity within tumors. Previous work in our lab focused on optimization of the polyplex core-forming block, resulting in the identification of a leading composition containing a balanced ratio of cationic and
dictate nature and level of adsorption or penetration by proteins and other molecules such as heparan sulfates.11 The most common and exhaustively explored surface modification method for increasing particle stability, reducing protein adsorption, and improving pharmacokinetics is the functionalization of particles with a PEG corona (PEGylation). The importance of PEG molecular weight, architecture, and surface density for increasing particle circulation time has been widely studied.12−16 However, proteins can penetrate PEG layers, resulting in opsonization, destabilization, and MPS accumulation.8,17 Additionally, many studies have shown that PEG can decrease overall target (i.e., tumor) cell uptake once the carrier reaches the desired tissue.17,18 A promising alternative to PEGylation is “zwitteration” of polyplex coronas. Zwitterionic surfaces are extremely hydrophilic because they are hydrated through strong electrostatic interactions, whereas PEGylated surfaces interact with water molecules through hydrogen bonding.19 Therefore, molecules that hydrate zwitterionic polymers are structured in the same way as in bulk water. This arrangement makes zwitterionic polymers thermodynamically unfavorable for protein adsorption, because there is no gain in free energy from displacing surface water molecules with protein. 19,20 In general, zwitterionic coronas have been shown to improve in vitro 5681
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affect the polyplex performance independent of corona chemistry.27 The 5k linear PEG, 10k PMPC, and 10k POEGMA corona lengths were chosen because they were the shortest corona lengths that would form relatively monodisperse polyplex structures. The 20k PMPC and 20k POEGMA were chosen as standards to compare to the 20 kDa Y-shaped PEG, which has been used in FDA-approved drugs for extending circulation time.14,31 Size and Stability Characterization of siRNA Polyplexes. Polyplexes were formed by first mixing polymer and siRNA at various N+:P− ratios (number of protonated polymer amines:number of siRNA backbone phosphates) in pH 4.0 citrate buffer, and then the pH was raised to 7.4 (Figure 1). Based on a Ribogreen assay, all polyplexes reached an encapsulation efficiency of around 75−80% by N+:P− 10, and slightly higher encapsulation efficiencies were achieved at N+:P− 20 (Figure 2A). To determine the best N+:P− ratio to use in subsequent testing of this library of polymers, we evaluated the average stability differences between polyplexes at N+:P− 10 and N+:P− 20 after a brief (30 min) incubation in 30% fetal bovine serum (FBS). By measuring the Förster resonance energy transfer (FRET) signal between coencapsulated fluorescent siRNAs relative to the signal of polyplexes unchallenged by FBS, we observed a decrease in average stability of all polyplexes at N+:P− 10 relative to N+:P− 20. Average stability ranged from 75 to 86% FRET at N+:P− 20 and from 42 to 48% FRET at N+:P− 10 (Figure 2B). Because of these results, we selected the N+:P− 20 ratio for all further studies. At this short serum incubation time, there were no significant differences between polyplexes of different coronas at a given N+:P− ratio. Importantly, despite their varied corona molecular weights and characteristics, all polyplexes had similar average hydrodynamic diameters of approximately 100 nm and showed no significant differences in surface charge (near neutral zeta potential) (Figures 2C−I and S4). Thus, although size and surface charge are known to affect pharmacokinetics, these factors were constant among each of the polyplexes despite different hydrophilic block chemistries.10 Polyplex size and stability evaluated under increasing salt concentrations showed that size of most polyplexes was only slightly affected by the addition of 0.1 M salt (Figure 2D−I). However, at 0.25 M NaCl, the 20k PMPC and 20k PEG polyplexes appeared most resistant to destabilization by increasing salt concentrations, while the 5k PEG and POEGMA corona polyplexes lost their uniform size distribution. This result suggests that larger coronas improved stability for linear PEG and zwitterionic PMPC coronas, but in the case of POEGMA-based polyplexes, increasing corona size did not improve stability. Polyplexes made with the longer 20k POEGMA corona, in addition to being less stable than other polyplexes, were also more polydispersed at baseline in low-salt conditions compared to other polyplexes. This is possibly due to excessive bulkiness, making it more difficult for this polymer to form tightly packaged micelles through electrostatic interactions in the core.32 While these POEGMA polymers were selected because the 950 Da side chains form more hydrophilic blocks than 300 Da OEGMAs, high molecular weight monomers are not as well studied as shorter OEGMA monomers, and their extended side chains may cause considerable steric repulsion between coronaforming blocks, a potentially destabilizing factor.29,33 In order to maximize polyplex accumulation at the site of the tumor, polyplexes must resist destabilization in circulation.4
hydrophobic monomers (dimethylamino ethyl methacrylate (DMAEMA), and butyl methacrylate (BMA), respectively).27 This optimization study solely utilized 5 kDa linear PEG as the corona-forming block. Here, we preserved the optimal coreforming DMAEMA-co-BMA composition and chain extended various corona-forming blocks in order to dissect the impact of corona chemistry on in vivo stability, pharmacokinetics, tumor accumulation, and tumor gene knockdown. We and others have sought to improve PEGylated nanocarrier pharmacokinetics through the use of a brush-like PEG architecture or high molecular weight Y-shaped PEGs, to varying degrees of success.14,15,28−30 In this study we compared PMPC coronas to these PEG architectures in addition to the linear 5 kDa PEG. We analyzed these polyplex surface materials using a number of techniques that quantify protein adsorption, polyplex stability, in vitro uptake and bioactivity, as well as in vivo pharmacokinetics and tumor gene silencing activity.
RESULTS AND DISCUSSION Synthesis of Diblock Copolymers with Varied CoronaForming Polymer Blocks. Six diblock copolymers were synthesized with a pH-responsive block comprising a random copolymer of dimethylaminoethyl methacrylate (DMAEMA) and butyl methacrylate (BMA) at equimolar ratio and a total degree of polymerization of approximately 150. The polyplex corona-forming blocks consisted of 5 kDa linear PEG, 20 kDa linear Y-shaped PEG, 10 kDa poly(oligo(ethylene glycol) methyl ether methacrylate) (POEGMA), 20 kDa POEGMA, 10 kDa zwitterionic PMPC, or 20 kDa zwitterionic PMPC corona (Figure 1). The 5 kDa linear PEG and 20 kDa linear Y-shaped PEGs were purchased, conjugated to the RAFT (revesible addition-fragmentation chain transfer) chain transfer agent, and then chain extended with RAFT to form the core-forming DMAEMA-co-BMA block. For the POEGMA and PMPC polymers, the core-forming DMAEMA-co-BMA block was first RAFT-polymerized and was subsequently extended using RAFT to polymerize two variants of each hydrophilic block composition near their target molecular weights of 10 kDa and 20 kDa. All diblock polymers were well-matched in terms of consistent DMAEMA-co-BMA block size and composition (approximately 150 degrees of polymerization with 50% of each monomer), and all polymers tested had relatively low polydispersity indices (PDI) ranging from 1.0 to 1.3 (Table 1, 1H NMR methods detailed in Supporting Information Figures S1−S3). These properties were important to control because small changes in core length or composition could Table 1. Polymer Molecular Weights (1H NMR), Monomer Compositions (1H NMR), and Polydispersity indices (Gel Permeation Chromatography) polymer 5k PEG 20k PEG 10k PMPC 20k PMPC 10k POEGMA 20k POEGMA
total MW (g/mol)
corona MW (g/mol)
% BMA
% DMAEMA
28636 43353 34129 45044 34171
5000 20000 10177 21092 11716
50 50 51 50 47
50 50 49 50 53
1.021 1.071
42619
18667
49
51
1.296
PDI
a a
1.156
a
PMPC polymers were not analyzed with GPC due to insolubility in mobile DMF phase. 5682
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Figure 2. Polyplexes with different corona chemistries have similar size, zeta potential, and cargo loading but varied stability against high salt concentrations. (A, B) Polyplex siRNA encapsulation efficiency and stability is highest at N+:P− 20. (A) Ribogreen assay reveals polyplex encapsulation plateaus by N+:P− ratio of 10. (B) Polyplexes retain higher stability after a 30 min incubation in 30% FBS at N+:P− 20 compared to N+:P− 10 (p < 0.01, n = 3). (C) All polyplexes were around 100−145 nm in average size. (D−I) Dynamic light scattering traces show that 20k PMPC and 20k PEG populations are more resistant to high salt conditions (N+:P− 20).
mL heparin, only decreasing in average FRET signal by 40 and 36%, respectively, while the FRET signal in all other polyplex samples decreased by 56−63%. At each heparin condition, 10k POEGMA was intermediately stable, and this was most apparent at 20 U/mL heparin, when 10k POEGMA did not diverge from 20k PEG and 20k PMPC until roughly 55 min of incubation. The other polyplexes, 5k PEG, 10k PMPC, and 20k POEGMA, were consistently the least heparin stable. While larger corona molecular weight improved stability for linear PEGylated and zwitterated polyplexes, this advantage did not hold true for POEGMA coronas. This could possibly be due to unfavorable steric properties of the bulky POEGMA side chains, which could potentially reduce core stability at baseline.32 While some heparin may be a binding free, uncomplexed polymer, the results of our Ribogreen assay (Figure 2A) indicate that the packaging of siRNA is the same for all polyplexes at N+:P− 20, so the molar amount of free polymer is consistent between all polyplexes and unlikely to influence these comparisons. Heparin binding free polymer is also unlikely based on the polyplex DLS traces (Figure 2D−I) that do not show evidence of free polymer and because any uncomplexed polymer in solution is micellar (due to the presence of hydrophobic BMA in the core-forming block), thus making DMAEMA unavailable for binding.27
The main sources of polyplex instability in the blood circulation include serum and anionic heparan sulfates in the kidney glomerular basement membrane, the latter of which can interact with positively charged components of siRNA polyplexes and result in decomplexation.5−7 To determine the impact of particle surface chemistry on polyplex stability, we challenged polyplexes containing FRET pair-loaded siRNA with serum or heparin salts. We found that at higher serum levels (30%), alternative corona chemistries improved stability compared to 5k linear PEG coronas, but there were few stability differences between individual coronas (Figure S5). At 10% serum, all polyplexes at N+:P− 20 resisted destabilization regardless of corona block (Figure S5). As shown previously in Figure 2B, polyplex N+:P− ratio appeared more important for short-term serum stability than corona block differences. Heparin salt-induced destabilization showed a greater dependency on corona composition. In heparin salts at a range of concentrations (Figure 3A−C), 20k PEG and zwitterionic 20k PMPC coronas provided the greatest stability over time compared to all other polyplex coronas. In 100 U/ mL heparin over 100 min, the average FRET signal for 20k PMPC and 20k PEG samples was significantly higher than that of 5k PEG, 20k POEGMA, and 10k PMPC (p < 0.05), indicating greater resistance to charge-induced destabilization. The 20k PMPC and 20k PEG also performed best with 60 U/ 5683
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were independent of polyplex concentration in the range tested (Figure S6). We next screened for toxicity of all polyplexes in luciferaseexpressing NIH3T3 fibroblasts (Figure 4B), in order to determine whether the polyplexes were harmful to normal and noncancerous cells. At 48 h post-treatment, none of the polyplexes significantly affected viability levels relative to untreated cells, with the exception of 10k PMPC. Average viability of 10k PMPC was still quite high, at 87%, indicating it was also relatively nontoxic. We also evaluated cytotoxicity of all polyplexes bearing scrambled siRNA in MDA-MB-231 cancer cells. All cell viability values were still >75% after 48 h incubation with high polyplex concentrations (Figure S7). We next evaluated uptake of polyplexes by MDA-MB-231 breast cancer cells (Figure 4C). Overall, polyplexes made with smaller molecular weight corona blocks had significantly higher mean fluorescence intensities compared to more shielded polyplexes comprising longer corona-forming blocks (p < 0.001, n = 3). In comparing different polyplex corona-forming block chemistries, the mean fluorescence intensity of 20k PMPC was >20k PEG polyplexes, and 10k PMPC had the highest uptake levels overall (p < 0.001, n = 3). For in vitro uptake, lower molecular weight coronas are often associated with increased cell uptake, because the cationic PDMAEMA components are less shielded.35 However, polyplexes made with shorter corona-forming blocks are generally less stable and therefore likely to produce less favorable in vivo pharmacokinetic properties. We also stratified polyplex uptake based on the percent of cells found within low, medium, and high uptake subsets (Figures 4D and S8a) in order to further interrogate differences in the distribution of polyplex uptake levels within the different treated cell populations. The 20k PEG had the highest percent of polyplex uptake positive cells in the low uptake group by a significant margin (p < 0.001), with 47% of cells in this group, while all other polyplex types ranged from 31 to 36% of cells in the low uptake group. In comparison, 10k PMPC had the highest percent of cells in the high group, at 31%. While more shielded than both 5k PEG and 10k POEGMA, 20k PMPC had a similar percent of cells in the “high” uptake category (14−17%) as the shorter corona polyplexes. In the high uptake category, 20k PEG polyplexes had the lowest percent of cells (8.9%), after 20k POEGMA (1.22%), which was significantly lower than the percent of cells treated with 20k PMPC polyplexes in the high category (8.9% vs 15%, p < 0.04). These combined data provide support that PMPC-based coronas have higher cell uptake properties compared to their PEGylated counterparts, suggesting that zwitterionic coronas provide polyplexes with stealth properties without limiting polyplex uptake as significantly as incorporation of high molecular weight PEG coronas. These data suggest that PMPC is less susceptible to the well-described “PEG dilemma” in drug delivery.8 Histograms of these cell populations can be found in Figure S8b. After confirming pH-responsiveness, cytocompatibility, and tumor cell uptake behavior of the polyplexes, we evaluated knockdown of the model gene luciferase in luciferaseexpressing MDA-MB-231 breast cancer cells (Figure 4E), across a range of doses. At the highest dose of 100 nM siRNA after 48 h, cells exposed to 5k PEG, 20k PEG, or either PMPC corona all retained